NO316010B1 - Method of handover, as well as cellular communication system - Google Patents

Abstract

The invention relates to a cellular communication system and a method for handover in a cellular communication system comprising at least one base station (BTS). for each cell, which base station is controlled by a base station controller (BSC) which controls one or more base stations, and which base station controller together with the base stations under its control forms a base station system (BSS). In order to achieve interference-free transmission in accordance with the invention, the service areas of base stations under different base station controllers (BSC1, BSC2) overlap at the boundary of two or more base station systems (BSSI, BSS2) at least in part, terminal equipment (PIS) moves from one base station system (BSC1) to another (BSC2), the handover is performed in such a way that when the terminal equipment moves into a cell served by two or more base stations (BTS11, BTS21) belonging to areas with different base station controllers, the terminal equipment performs a soft handover from the old cell (BTS 12) to the new cell (BTS11), and as it moves further towards the cell boundary, it performs a hard handover from the base station (BTS11) in the old base station system (BSSI). to the base station (BTS21) in the new base station system (BSS2), and this base station (BTS21) has service area that overlaps at least partially with the previous base station.

Description

The present invention relates to a method for handover in a cell-shared communication system which comprises at least one base station for each cell, and where the base station is controlled by a base station control unit which controls one or more base stations, the base station control unit together with the base stations that are under its control form a base station system.

The present invention is particularly well applicable in cell-divided CDMA communication systems. A CDMA system ("Code Division Multiple Access") is a multiple access method that is based on spread spectrum technology, and which has recently begun to be used in cell-division communication systems alongside the previous FDMA and TDMA technologies ("Frequency Division Multiple Access", "Time Division Multiple Access", "Time Division Multiple Access") CDMA technology has several advantages over the previous methods , such as spectral efficiency, simple frequency planning and traffic capacity.

In a CDMA method, the user's narrowband data signal is multiplied by a spreading code with a much wider bandwidth, into a relatively wide traffic channel band. In the known, experimental, cell-shared network systems, for example, the bandwidths used on traffic channels include 1.25 MHz, 10 MHz and 25 MHz. In the multiplication process, the data signal spreads to the entire band that is used. All users transmit simultaneously by using the same frequency band, i.e. the same traffic channel. A separate spreading code is used for each connection between a base station and a subscriber terminal equipment, and the signals from the users can be identified from each other in the receivers on the basis of each connection's spreading code.

In a CDMA system, all users thus transmit on the same and relatively wide frequency band. The user's traffic channel is formed by a spreading code that is characteristic of the connection, and on the basis of the spreading code, the transmission from the user is identified in relation to the transmissions from other connections, as previously described. As a considerable number of spreading codes are usually in use, the CDMA system does not have a definite capacity limit like the FDMA and TDMA systems. The CDMA system is a so-called interference-limited system where the number of users is limited by the level of interference that one user is allowed to cause to another. As the users' spreading codes in the systems in use are not completely uncorrelated with respect to the spreading codes used in the neighboring cell, as a special case, simultaneous users cause interference for each other to a certain extent. This type of interference caused by one user to another is referred to as multi-user interference. As the number of users increases, the level of interference they cause to each other increases accordingly, and when the number of users reaches a certain level, the interference increases to such an extent that the quality of the connections is destroyed. In the system, it is possible to determine an interference level that must not be exceeded, and thus a limit is set for the number of simultaneous users, i.e. a limit to the system's capacity. However, a temporary exceedance of this number can be allowed, which means that some of the connection quality is sacrificed in favor of the capacity.

In a typical mobile station environment, the signals travel between a base station and a mobile station via several different paths between the transmitter and the receiver. This multipath propagation is mainly caused by signals being reflected from surrounding surfaces. Signals that have traveled different paths arrive at the receiver at different times due to the different propagation time delays. The CDMA method differs from the conventional FDMA and TDMA methods in that in the CDMA method multipath propagation can be used when receiving signals. A so-called RAKE receiver consisting of one or more RAKE branches is usually used as a CDMA receiver solution. Each branch is an independent receiver unit with the function of composing and demodulating a received signal component. Each RAKE branch can be controlled to synchronize with a signal component that has traveled along a separate path, and in a conventional CDMA receiver the signals in the receiver branches are combined with advantage, and thus a signal with good quality is obtained.

It is possible that the signal components received by the branches of a mobile station's CDMA receiver have been transmitted by one or more base stations. In the latter case, it is about so-called macro-diversity, i.e. a diversity mode by which the quality of a connection between a mobile station and a base station can be improved. In cell-divided CDMA communication networks, macro-diversity, which is also referred to as "soft handover", is used to ensure operation with power management at the base station's border areas, and to enable a smooth handover. A mobile station using macro-diversity thus communicates simultaneously with two or more base stations. All connections transmit the same information. As an example of a communication system using macro-diversity, reference can be made to the publication EIA/TIA Interim Standard: Mobile Station-Base Station Compatibility Standard for Dual-Mode Wideband Spread Spectrum Cellular System, TAI/EIA/IS-95, July 1993 .

In a situation with macro-diversity, the terminal equipment can thus combine signals sent by different base stations. On the base station's side, signals received by two separate base stations from the terminal equipment are combined at the first possible point, which in most cases is the base station control unit in the area of which the base stations are located. If the base stations to which the terminal equipment is connected are under the control of different base station control units, the practical implementation of a soft handover will be considerably more complicated, because in such a case the interconnection must be carried out in a mobile service telephone exchange.

Older cellular communication systems, such as GSM, NMT and AMPS, use a so-called hard handover where the base station handover is performed by first breaking the connection with the old base station, and then establishing a connection with a new base station. In such a case, the terminal equipment is connected to only one base station at a time. Hard handover technology is easier to implement than soft handover. Until now, hard handover has not been used in CDMA systems, because it causes instability in the power management. Because the system is interference-limited, accurate power management is a requirement when operating a CDMA system.

It is an object of the present invention to make it possible to use both soft and hard handover especially in a cellular CDMA communication system, so that the advantages of both methods can be achieved.

This is achieved by means of a method of the type presented in the introductory paragraph, which is characterized by the fact that at the boundary of two or more base station systems the service areas of base stations under different base station control units overlap at least partially, and that when a terminal equipment moves from one base station system to another, the handover is performed in such a way that when the terminal equipment moves into a cell served by two or more base stations belonging to the areas of different base station controllers, the terminal equipment performs a soft handover from the old cell to the new cell, and as it moves further towards the cell's boundary, it performs a hard handover from the base station in the old base station system to the base station in the new base station system, which base station has a service area that at least partially overlaps with the former base station.

The invention further relates to a cellular communication system which comprises in each cell at least one base station which is controlled by a base station control unit which has one or more base stations under its control, and which base station control unit with the said base stations under its control constitutes a base station system . It is characteristic of a cellular communication system according to the invention that at the border area of two or more base station systems the service areas of base stations under the control of different base station control units overlap at least partially, and that when a terminal equipment in the system moves into a cell that served by two or more base stations belonging to areas with different base station controllers, the terminal equipment is arranged to perform a soft handover from the old cell to the new cell, and when it further moves towards the cell boundary, the system terminal equipment is arranged to carry out a hard handover from the base station in the old base station system to the base station in the new base station system, this base station's service area at least partially overlapping with the former base station.

By means of the method according to the invention, the power management of the network remains stable even when hard handover is used, and the complexity of a soft handover at the boundary between two base station control units can be avoided.

With the help of the invention, the use of soft handover and hard handover technology can be combined in such a way that if a subscriber terminal equipment is located within a base station system, it is handed over from one base station to another through a soft handover, and the base station the change to the area of the new base station controller is performed through a hard handover. In an implementation in accordance with the invention where the service areas of base stations located at the border of base station control units overlap, the problems that the hard handover previously caused on the system's power management are avoided.

In what follows, the invention will be described in more detail with reference to the attached drawings, where

Fig. 1 is a block diagram with an exemplary illustration of the structure of a cell division

communication system,

Fig. 2 is an exemplary illustration of a cellular communication system in accordance

with the invention,

Fig. 3a - 3c are exemplary illustrations of a base station design, and

Fig. 4 illustrates the function of the method according to the invention.

Figure 1 illustrates a typical structure for a cellular communication system. The area covered by the system is typically divided into base station systems 6SS, each of which consists of a base station control unit BSC, and base stations BTS connected to this BSC, which base stations serve the subscriber terminal equipment MS located in their service area. The base station control units are again typically connected to mobile service centers MSC from which calls are routed to the fixed network, and to other mobile service centers.

In a typical system using soft handover, the control functions for the base station system BSS are concentrated in a base station control unit BSC. A base station BTS handles the operations for the physical layer, such as sending and receiving the signal over the radio path, and is largely a transparent component when considering signaling between the terminal equipment and the higher level of the system. Typical functions for a base station control unit include, for example, management of radio resources in the base station system BSS, connection of signals between base stations BTS and the rest of the network, management of macro-diversity, and balancing of power management in the entire BSS area.

The structure of a cellular communication system is illustrated in figure 2. The figure shows a number of cells in the system, and each cell is served by a base station. The system's area in the figure is divided into four base station systems A, B, C and D, see such markings in the figure. In a cellular communication system according to the invention, the cells located in the border area between the base station systems are served by two base stations that belong to areas for different base station control units. In the figure, these cells are marked with two letters, for example AB, which cell is thus served by base stations under the control of the base station systems A and B.

The operations of the two base stations are independent of each other, but because their coverage areas and propagation conditions are identical, their operations do not interfere with each other. Both base stations independently control the transmit power levels of the terminal equipment to which they are connected. Both base stations also operate in the same frequency range, but they use different spreading codes. Due to the identical coverage area, the interference level for both base stations is identical, and thus the power management functions are balanced as in a situation where a cell is served by a base station. However, it should be noted that the combined capacity of the base stations is the same as in the case of a cell comprising a base station, because the total cell interference, which limits the cell's capacity, is the same in both cases.

Overlapping cells usually comprise two base stations, but in the corners of the base station systems it may be necessary to use a combination of, for example, three or even more base stations. In the example in Figure 2, the central cell, which is located at the node for four base station systems, comprises base stations under the control of four base station control units A, B, C and D.

In the example in Figure 2, there are cells with a depth of one cell, but at the border of BSS areas it is also possible to use overlapping cells with a depth of two cells. The network planning must be carried out in such a way that no situation occurs where a terminal equipment must be in a soft handover situation for base stations in different base station systems. A situation like this can always be blocked, if there is sufficient depth in the overlapping of cells.

Base stations serving the same geographical area can be implemented in several different ways, some of which are illustrated in Figures 3a-3c. Figure 3a illustrates an example where base stations are implemented as units 30, 31 which are totally independent of each other, and where both have separate antennas 32, 33. The antennas should be placed close to each other so that the radio path for both cells has the same propagation conditions. Each base station is connected to a separate base station control unit 34, 35. Figure 3b shows a preferred embodiment of the invention, where the actual base station equipment 30, 31 is separate, but uses the same antenna 32. In such a case, the costs for a base station are lower than in the version mentioned earlier, because the antenna and mast costs are lower. Figure 3c illustrates a second preferred embodiment of a cellular communication system in accordance with the invention, where overlapping base station equipment is implemented by dividing a physical base station equipment 36 into two logical sections 30, 31 which are under the control of different base station control units 34, 35 and uses the same antenna 32. The base stations 30, 31 thus use the same physical resources, except that the equipment must have separate connections for two base station control units.

In the following, the method according to the invention will be described in more detail with the help of figure 4. The figure shows two base station control units BSC1 and BSC2. Of the base stations under the control of the first base station control unit BSC1, the base stations BTS11-BTS14 are shown in the figure. Of the base stations under the control of the second base station control unit BSC2, the base stations BTS21-BTS25 are shown in the figure.

The subscriber terminal equipment MS moves in the BSC 1 area towards the BSC2 area. When the terminal equipment moves from one cell to another, the base station controller BSC1 takes care of the handovers and the stability of the power control. The handovers are performed as soft handovers so that a connection with the new base station is established before the old connection is broken.

Let us assume that a terminal equipment MS moves from the cell 40 served by the base station BTS12 to the cell 41 located at the border between the two mentioned base station systems. The cell is served by two overlapping base stations, BTS11 and BTS21. BTS11 is connected to the control unit BSC1, and BTS21 is connected to the base station control unit BSC2. When the terminal equipment moves to cell 41, it performs, under the control of BSC1, a soft handover to a traffic channel for base station BTS11.

Let us further assume that the terminal equipment moves towards cell 42 and finally into that area. The base station BTS22 serving cell 42 is under the control of BSC2. Before it is possible to activate the base station BTS22 for the handover, the first call control must be switched over to the base station control unit BSC2 from the previous control unit BSC1. This is done using a hard handover. The terminal equipment performs a hard handover from the base station BTS11 to the base station BTS21, and accordingly the change of base station controller from BSC1 to BSC2 will take place. In a hard handover, it is the spreading code used by the terminal equipment that changes. When the handover on the part of the terminal equipment is carried out in the same cell, there are no sudden changes in the power management.

If, at the moment when the handover is carried out, the terminal equipment is simultaneously connected to several base stations serving overlapping cells, the hard handover is also carried out at these base stations at the same time. A situation such as this is possible especially in cases where there are overlapping base stations with a depth of several cells in the border areas between base station systems. The terminal equipment is thus now under the control of the base station control unit BSC2, and as it moves deeper into the cell 42, it can perform a soft handover to a base station channel BTS22 in the normal way.

Claims (9)

1. Method of handover in a cell-shared communication system comprising at least one base station (BTS) for each cell, which base station is controlled by a base station controller (BSC) which controls one or more base stations, and which base station controller together with the base stations under its control form a base station system (BSS), characterized in that at the boundary of two or more base station systems (BSS1, BSS2) the service areas of base stations under different base station control units (BSC1, BSC2) overlap each other at least partially, and that when a terminal equipment (MS) moves from a base station system (BSC1) to another (BSC2), the handover is performed in such a way that when the terminal equipment moves into a cell served by two or more base stations (BTS11, BTS21) belonging to areas of different base station controllers, the terminal equipment performs a soft handover from the old cell (BTS12) to the new cell (BTS11), and when it further moves towards the cell boundary, it performs a hard handover from the base station (BTS11) in the old base station system (BSS1) to the base station (BTS21) in the new base station system (BSS2), as this base station's (BTS21) service area at least partially overlaps with the former base station. 2. Method according to claim 1, characterized in that if the terminal equipment at the moment when the hard handover is performed is simultaneously connected to several base stations located in cells where the service areas of base stations belonging to areas of different base station control units overlap at least partially, the hard handover is performed simultaneously in all cells. 3. Method according to claim 1, characterized in that a hard handover between two base stations (BTS11, BTS21) is activated in cases where the connection quality between a terminal equipment (MS) and the old base station (BTS11) deteriorates below a predetermined threshold. 4. Cell-shared communication system which in each cell comprises at least one base station (BTS) which is controlled by a base station control unit (BSC) which has one or more base stations under its control, and which base station control unit together with the said base stations under its control, form a base station system (BSS), characterized in that in the border area of two or more base station systems (BSS) the service areas of base stations under the control of different base station controllers overlap at least partially, and that when a terminal equipment in the system moves into a cell served by two or more base stations (BTS11, BTS21) belonging to areas with different base station controllers, the terminal equipment is arranged to perform a soft handover from the old cell (BTS12) to the new cell (BTS11), and when it moves further towards the cell boundary, the system's terminal equipment is arranged to perform a hard handover from the base station (BTS11) in the old base station system (BSS1) to the base station (BTS21) in the new base station system (BSS2), this base station's (BTS21) service area being at least partially overlaps with the previous base station. 5. Cellular communication system according to claim 4, characterized in that at a boundary of two or more base station systems (BSS) there are at least partially overlapping base stations which are under the control of different base station control units with a depth of two cells. 6. Cellular communication system according to claim 4, characterized in that in a cell located at the node point for two or more base station systems (BSS), the base stations are controlled by all the base station systems that border the cell. 7. Cellular communication system according to claim 4, characterized in that overlapping base stations (BTS11, BTS21) are implemented using two separate base station equipment. 8. Cellular communication system according to claim 4, characterized in that the overlapping base stations (BTS11, BTS21) have common antennas. 9. Cellular communication system according to claim 4, characterized in that overlapping base stations (BTS11, BTS21) are implemented by logical division of one base station equipment to be controlled by two separate base station control units (BSC1, BSC2).